Inclined artifical fur and method of manufacturing the same

ABSTRACT

The present invention provides an artificial fur of a rising hair structure formed by implanting pile fibers through a base fabric, characterized in that the pile fibers are inclined generally longitudinally, as viewed from above the surface, the pile fibers in the widthwise central section of the rising hair structure extend in parallel to the longitudinal direction, the pile fibers in the opposite peripheral sections extend diagonally widthwise with respect to the longitudinal direction and the pile fibers in the outermost sections of the rising hair structure extend diagonally at angles in the range from 10 to 80 degrees with respect to the longitudinal direction of the rising hair structure. The present invention enables stable and economic mass production of such an artificial fur by means of a liquid-flow treatment machine.

DESCRIPTION

1. Technical Field

The present invention relates to an artificial fur and a method of manufacturing the same.

2. Background Art

Furs, such as mink as a typical example, have been long appreciated as an excellent clothing material, e.g., for shawls and coats, and as upholstery and architectural decorative materials, such as for sofas, car seats, rugs, and tapestries, because of their excellent touch, luster, hand, and appearance.

Example of artificial fur manufacturing techniques are disclosed Japanese Unexamined Patent Publication (Kokai) Nos. 56-63057 and 57-121643. The artificial fur manufactured according to the former has a rising hair structure formed by simply implanting fibers in an unreinforced ordinary base fabric through a needle punching process, while the artificial fur manufactured according to the latter has a rising hair structure formed by tufting fibers of different lengths in a wavy form. In either structure, the rising pile fibers are standing practically upright over the base fabric and cannot duplicate the lie of the hair and the appearance of a genuine fur, and hence, those artificial furs are readily distinguished visually from genuine furs. The artificial furs with such rising hair structures have a disadvantage in that the base fabric is exposed when bent. Furthermore, those techniques have an intrinsic problem in that they are able only to produce an artificial fur of reduced hair density, even if they are able to overcome the above-mentioned disadvantages of the artificial furs. These problems of artificial furs have not yet been solved.

DISCLOSURE OF THE INVENTION

Accordingly, it is an object of the present invention to provide an excellent artificial fur having the lie of hair, appearance and recovery from rubbing against the lie of hair, all of which are not inferior to those of genuine furs.

It is another object of the present invention to provide an artificial fur having, in addition to the above-mentioned characteristics, a high hair density.

It is a further object of the present invention to provide an artificial fur of a ribbed construction consisting of a plurality of unit rising hair structures each having the above-mentioned characteristics.

It is still further object of the present invention to provide a method of manufacturing such artificial furs easily, stably and in large quantities.

The subject matter of the present invention is summarized as follows.

(1) An artificial fur of a rising hair structure formed by implanting pile fibers through a base fabric, characterized in that the pile fibers are inclined generally longitudinally and, as viewed from above the surface, the pile fibers in the widthwise central section of the rising hair structure extend in parallel to the longitudinal direction, the pile fibers in the opposite peripheral sections extend diagonally widthwise with respect to the longitudinal direction, and the pile fibers in the outermost sections of the rising hair structure extend diagonally at angles of 10 to 80 degrees with respect to the longitudinal direction of the rising hair structure.

(2) An artificial fur comprising a plurality of unit rising hair structures each according to the rising hair structure of the preceding paragraph.

(3) An artificial fur of a rising hair structure as mentioned in the preceding paragraph, characterized in that at least one side of the base fabric is coated with an elastomer.

Such artificial furs are manufactured through the following method.

(4) A method of manufacturing an artificial fur, comprising steps of forming a rising hair structure by implanting pile fibers in a base fabric through a needle punching process and passing the rising hair structure together with a liquid through a restricted space.

(5) A method of manufacturing an aritifical fur, employing a liquid-treatment machine having a restricted space mechanism comprising slits or nozzles, as means to pass the said rising hair structure together with a liquid through the restricted space.

(6) A method of manufacturing an artificial fur, characterized in that a film of an elastomer is formed at least over one side of the base fabric prior to implanting pile fibers in the base fabric through a needle-punching process; and

(7) A method of manufacturing an artificial fur, characterized in that the needle-punching process for implanting pile fibers in the base fabric employs a needle board having needles varying widthwise in needle depth so that the points of the needles form a coherent surface having longitudinal linear grooves.

Thus the constitution of the present invention enables the easy and stable mass production of an artificial fur having surface characteristics featured by the rising pile fibers, exceeding those of the genuine fur, which the prior art could not achieve.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional model view of an artificial fur according to the present invention, illustrating the general lie of the pile fibers;

FIG. 2 is a sectional model view taken along the width of a unit rising hair structure of an exemplary artificial fur according to the present invention;

FIG. 3 is a top plan view of the artificial fur of FIG. 2, showing the lie of the pile fibers;

FIG. 4 is a sectional model view of another artificial fur according to the present invention, consisting of a plurality of the rising hair structures of FIG. 2, and showing the mode of rising of the pile fibers;

FIG. 5 is a top plan view, in a model, of the artificial fur of FIG. 3, showing the lie of the pile fibers;

FIGS. 6 and 7 are sectional model views of examples of artificial furs according to the present invention having base fabrics coated with the films of an elastomer on the upper side and on both sides respectively;

FIG. 8A is a schematic sectional view of an example of an apparatus for passing a rising hair structure therethrough together with the rapid flow of a liquid, in manufacturing an artificial fur according to the present invention;

FIG. 8B is a schematic sectional view of a mechanism for passing a rising hair structure together with the rapid flow of a liquid through a restricted space, employed in the apparatus of FIG. 8A;

FIG. 9 is a sectional view of an example of a needle board for needle punching pile fibers, employed in manufacturing an artificial fur according to the present invention;

FIG. 10 is a sectional view of an example of a needle board employed in manufacturing an artificial fur consisting of a plurality of unit rising hair structures according to the present invention;

FIG. 11 is a sectional view of a needle board having needles of different lengths arranged so that the points thereof form a wavy coherent surface;

FIGS. 12A, 12B, and 12C are fragmentary views of needles employed in the apparatus for manufacturing an artificial fur according to the present invention; and

FIGS. 13 and 14 are photographs of an example of an artificial fur according to the present invention, corresponding to FIGS. 3 and 4 respectively, shown for reference. Dark portions in the photographs are shades resulting from the relative disposition of the artificial fur with respect to the photographic lighting apparatus.

BEST MODE FOR CARRYING OUT THE INVENTION

The term "pile fibers" 1 (designated as "piles" hereinafter) used in the description of the present invention represents staple fibers selected among natural fibers or synthetic fibers. Staple fibers used as guard hair fibers 1a (designated as "guard fibers" hereinafter) and staple fibers used as underfur fibers 1b (designated as "under fur fibers" hereinafter) are different from each other in length. Ordinarily, guard hair fibers 1a are longer than under fur fibers 1b. However, it is preferable that the fiber length be the same among the guard hair fibers or among the under fur fibers.

This invention uses the guard hair fibers 1a and the under fur fibers 1b individually or in combination. When guard hair fibers 1a and the under fur fibers are used in combination, the range of the ratio of the amount of the guard hair fibers to the total amount of the pile is 20 to 60% by weight, preferably, 30 to 50% by weight, in view of the touch, appearance, hand, and the lie of hair.

The guard hair fibers 1a may be crimped somewhat, however, straight fibers are preferable, whereas, preferably, the under fur fibers are crimped fibers. The preferable mode of crimp is 4 to 10 crimps/25 mm in number and 3 to 8% in percentage crimp. Fine crimped fibers having crimps of a number around the lower limit of the range of the number of crimps as used as under fur fibers have desirable properties, such as the prevention of the exposure of the base fabric and the improvement of the apparent hair density. Straight fibers as designated herein are practically linear fibers having crimps of a number below the range of the number of crimps.

Fibers used as guard hair fibers 1a are those of approximately 20 to 70 d fineness and 20 to 40 mm fiber length, while fibers used as under fur fibers 1b are those of approximately 1 to 7 d fineness and 15 to 30 mm fiber length. Further, if necessary, extra-fine fibers of 1 d or less, e.g., 0.1 d˜0.001 d may be used as under fur fibers. However, those values defining the quality of fibers are subject to change depending on the design of an artificial fur to be produced.

The pile materials may be natural fibers, however, in view of the characteristics of the pile, processing facility, and availability, synthetic fibers are preferable. Preferable synthetic fibers, for instance, are fibers of the polyester group, the polyamide group, the polyacrylonitrile group, and the acetate group. Among those synthetic fibers, those of the polyester group and the polyamide group are preferable in view of the facility in tapering fibers. Fibers of the polyester group are particularly preferable, because they can be easily be processed in an alkaline aqueous solution to produce fibers of a beautiful taper form having a pointed tip. Among the fibers of the polyester group, the fibers of polybutylene terephthalate are suitable for forming long taper fibers. Fibers of polybutylene terephthalate and nylon 66 have excellent impact resilience, and hence, those fibers are desirable fibers for pile 1, particularly for guard hair fibers 1a.

There is no any restriction on the morphology of fibers for forming the pile, however, fibers of special sections having axial ridges, such as fibers of flat cross section or X-shaped cross section, are preferable in view of their resistance to yielding, elasticity, and luster. These fibers are particularly useful for guard hair fibers 1a.

Fibers tapering at least in one end thereof are preferable for forming the pile 1. Tapered guard hair fibers 1a, in particular, remarkably improve the touch and hand of the pile.

Taper fibers are produced by a chemical process in which fibers are dissolved or decomposed, a physical process in which fibers are broken by drawing, or a combination of those processes. A chemical process, above all, is capable of easily producing taper fibers of preferable fiber characteristics. In the case of fibers of the polyester group, fibers are hydrolyzed and tapered readily by an alkaline aqueous solution by a method, for instance, disclosed in Japanese Unexamined Patent Publication (Kokai) No. 54-38922 or in Japanese Examined Patent Publication (Kokoku) No. 50-40915.

The term "rising hair structure" 2 (designated as "pile rib" hereinafter) is used herein to designate a longitudinal band 8 of piles 1 of a fixed width formed by implanting piles 1 through a base fabric 3.

The pile rib 2 formed of piles 1 implanted through the base fabric 3 is a rising hair structure having piles implanted mainly through the needle punching process, in which some of the piles 1 may be gripped in the interior of the base fabric 3. The width of the band 8 is optional, however, in view of the surface characteristics provided by the piles 1 (surface variation), the preferable width is 20 cm or less. When the width of the band 8 is 3 to 15 cm in particular, the surface characteristics are conspicuously exhibited.

The artificial fur may be a structure formed of a single unit pile rib 2 or a structure consisting of a plurality of the unit pile ribs 2 arranged in a continuous arrangement or in an interrupted arrangement. However, in the case of an artificial fur of a structure consisting of a plurality of the unit pile ribs 2 arranged in an interrupted arrangement, the sections not having any pile may be cut off and the unit pile ribs 2 sewn together.

In forming the pile rib 2, the arrangement of longer piles 1 in the central area and shorter piles 1 in the peripheral area of the pile rib 2 facilitates forming inclined piles 1 featuring the characteristics of the artificial fur according to the present invention, and hence, such an arrangement of piles 1 is preferable to the arrangement of piles 1 of the same lengths over the pile rib 2 in a widthwise direction X of the rising hair structure. In particular, it is desirable to arrange piles 1 of different lengths so that the piles 1 decrease in height gradually from the central area toward the peripheral areas of the pile rib 2 (triangular arrangement).

In such an arrangement of differential pile height, it is preferable that the length of the piles in the central area be longer than the length of the piles in the peripheral areas by approximately 10 to 40%, in view of providing the characteristic lie of the hair of the artificial fur according to the present invention. Such characteristic lie of the hair is provided also when the central area is greater than the peripheral areas in pile density. The pile rib 2 with a pile density of the central area greater than that of the peripheral areas by 20 to 50% is preferable in order to attain the object of the present invention. Pile length and pile density are interactive. A suitable combination of pile length and pile density brings about desirable results in this invention.

The central area corresponds to the central section among three equal sections of the band 8 divided widthwise where the piles are the same in length in the widthwise direction X of the rising hair structure, while where the piles of different lengths are arranged in a triangular form, the central area corresponds to the peak section. In the case of a band 8 varying in pile density by section, the central area corresponds to a section where the pile density is high. When both the pile length and the pile density are different between the sections, either one of the pile length or the pile density more significantly affecting the lie of hair can be the factor for deciding where the central area is. Ordinarily, the central area corresponds to the central section among three equal sections.

The inclination of the piles 1 of the band 8 along the longitudinal direction Y, as shown in FIG. 1, is a feature of the artificial fur of the present invention. The inclination of the piles 1 remarkably upgrades the luster of the artificial fur. The preferable angle of inclination of the pile 1 to the base fabric 3 is an angle within a range of approximately from 40 to 70 degrees. When the angle of inclination is greater than 70 degrees, the appearance of permanent set in fatigue is enhanced. On the other hand, when the angle of inclination is smaller than 40 degrees, the effect of shielding the base fabric 3 and the under fur fibers 1b is diminished and the touch and luster of the artificial fur tends to be deteriorated.

It is another feature of the present invention that the piles 1a are inclined generally longitudinally and, as viewed from above the surface, the piles 1a in the widthwise central section of the band 8 extend in parallel to the longitudinal direction Y of the band 8, the piles in the opposite peripheral sections of the band 8 extend diagonally widthwise with respect to the longitudinal direction Y, and the piles 1a in the outermost sections of the band 8 extend diagonally at angles of 10 to 80 degrees, preferably 20 to 70 degrees, with respect to the longitudinal direction Y as shown in FIG. 3. Such a three-dimensional mode of the lie of the hair is an incomparable feature of the artificial fur of the present invention. This feature is produced in the artificial fur formed of a single unit pile rib (FIG. 2) and also in the artificial fur consisting of a plurality of the unit pile ribs (FIG. 4) as illustrated in FIG. 5. FIGS. 13 and 14 are photographs of artificial furs embodying the present invention corresponding to the model diagrams of FIGS. 3 and 4 respectively, shown for reference. The dark portions in the photographs are shades resulting from the disposition of the artificial furs with respect to the photographic lighting equipment.

The extension of piles 1 practically in parallel to the longitudinal direction does not necessarily mean that the angle of the pile fiber to the longitudinal direction is zero degrees. The objects of the present invention can be attained as long as the piles 1 extend generally along the longitudinal direction even if the piles 1 are inclined slightly with respect to the longitudinal direction. Naturally, the effect of the present invention is conspicuous when the angle of the piles 1 with respect to the longitudinal direction Y is close to zero degrees. The angles of extension of all the piles 1 in the peripheral sections need not be the above-mentioned angles; the angles of those piles 1 may increase gradually from the area near the central section in the widthwise direction X of the rising hair structure toward the outermost area where the angle needs to be the above-mentioned angles.

If the angle of extension of the pile 1 is less than 10 degrees, it is hard to produce interference fringes, whereas if it is greater than 80 degrees, irregular interference fringes are produced due to excessive interference between the piles, which is not desirable from the aesthetic viewpoint and in respect of the appearance.

Only when the piles 1 are arranged in the mode as described hereinbefore, do the respective piles 1 in the outermost areas of the adjacent pile ribs 2 and extending outward interfere with each other between the adjacent pile ribs 2 to form a linear interference fringe between the adjacent pile ribs 2 as illustrated in FIG. 5.

As a customary practice, a high-grade fur formed of a fur such as mink is formed first by cutting a piece of fur into strips, and then the strips of fur are rearranged, through the let-out process. The let-out process makes the piles of the fur incline uniformly in parallel to the longitudinal direction, which spoils the beautiful interference fringes and the varied aesthetic surface appearance of a high-grade fur coat, even of mink.

The artificial fur of the present invention is extremely excellent and not at all the same as mink and fox in respect of the interference fringes of the piles and the varied aesthetic surface appearance.

A factor permitting such characteristics of the pile arrangement is a rising hair structure in which piles 1 are implanted through the base fabric 3 in bundles. According to the present invention, piles 1 are implanted by the needle punching process in which a plurality ot piles 1 are implanted in bundles in a single stroke needling operation. Such a rising hair structure is a characteristic feature of the present invention. In an artificial fur according to the present invention, a plurality of piles 1, irrespective of guard hair fibers 1a or under fur fibers 1b, are implanted in a single implantation point (a hole). This structure is an effective factor in the artificial fur of the present invention for satisfying the abovementioned pile arrangement, despite the fur being an artificial article. Furthermore, this structure improves the recovery of piles from rubbing against the lie of hair and prevents the falling-off of piles from the base fabric. Furthermore, this structure enables the rising hair structure to be processed in the successive wet treatment for as long a time as necessary for achieving the effect of the wet treatment, without any possibility of damage.

The recovery from rubbing against the lie of the hair as mentioned herein represents the stability of the pile recovery from a raised position to the original inclined position when rubbed against the lie of the hair. If the recovery from rubbing against the lie of the hair is inferior, the arrangement of the piles is unstable and the piles are liable to be thrown into disorder, which deteriorates the quality of the arrangement of the piles 1 when the artificial fur is worn.

Furthermore, the structural factors, such as the individual implantation of the pile bundles at individual implantation points and the random distribution of the individual pile bundles, also are effective factors prompting the characteristic arrangement of piles. That is, the individual implantation of pile bundles enables the successive wet treatment to completely remove the restraint due to implantation of pile bundles and functions effectively in forming the lie of the hair, while the random distribution of the pile bundles eliminates the uniform distribution of the piles 1 and the artificial appearance of the artificial fur.

It is a further feature of the present invention that a film 4 of a polymeric elastomer is formed at least over one side of the base fabric 3 as illustrated in FIGS. 6 and 7 to complete the pile characteristics. The provision of the film 4 remarkably improves the pile density, the strength of the artificial fur, and the prevention of the falling-off of the piles. Forming the films 4 over both sides of the base fabric enhances the effects of the improvement still further. The film 4 may be formed not only so that the film 4 or films 4 extend over the surface or the surfaces of the base fabric 3, but may be formed so that part of the film 4 permeates the base fabric 3 or the respective parts of the films 4 permeate the base fabric 3 from both sides of the base fabric 3 and join within the base fabric 3.

It is to be noted that the film 4 need not be a film virtually, but may be a partial distribution of an polymeric elastomer over the surface of the base fabric 3 in the form of a film 4. However, it is obvious that forming the film 4 over the surface of the base fabric 3 further improves the specific properties of the base fabric, such as the pile gripping capacity and the strength.

Forming the film 4 to at least a 1μ thickness, preferably a 10 to 50μ thickness, most preferably a 10 to 30μ thickness, over the surface of the base fabric 3 protects the base fabric 3 from damage due to needle punching, remarkably improves the dimensional stability of the base fabric 3, and enables the base fabric 3 to withstand high pile density. An excessively thin film is not capable of providing the above-mentioned effects of the film, whereas an excessively thick film stiffens and spoils the hand of the artificial fur.

Furthermore, the film 4 has a favorable property for implanting piles by needle punching. When needles 6 penetrates through the base fabric 3, pores expanded elastically by the needles 6 are formed, and after the needles 6 have been withdrawn, the pores contract elastically. Such elastic contraction of the pores holds the implanted piles 1 firmly.

Thus the simultaneous improvement of the property of the film 4 and the strength of the fabric 3 enables high-density pile implantation, never before thought of, and enables the reduction of the thickness of the base fabric 3 to the least possible extent, which significantly affects the flexibility of the artificial fur of the present invention. In this case of a nonwoven fabric, for instance, the upper limit pile density in implanting piles by needle punching is, at the highest, 200 g/m², and if piles are implanted excessively in disregard of hand and appearance, the base fabric is destroyed when the pile density is 300 g/m². Whereas, according to the present invention, a pile density as high as 500 g/m² or even more than 700 g/m² is possible. As regards the thickness of the base fabric 3, the possible lower limit of a thickness for forming an artificial fur is as small as a thickness corresponding to a unit weight of 50 g/m².

Elastomers of the urethane group, the acrylic group, the silicon group, and the fluorine group are suitable materials for the film 4. Above all, resins of the polyurethane group are preferable as materials of the film of the artificial fur of the present invention, because of their excellent elasticity.

Exemplary resins of the polyurethane group are various polyether polyurethanes, polyester polyurethane, and polyester polyether polyurethane. These resins are produced through reactions between long-chain diol (polyester or polyether), diisocyanate, and a chain extender of a low molecular weight (glycol or diamine). The base fabric 3 for supporting the piles 1 may be a woven fabric, a knitted fabric, a nonwoven fabric, or a sheet-form material of a combination of those fabrics. Nonwoven fabrics, in particular, are suitable materials of the base fabric, because nonwoven fabrics facilitate the adjustment of the hand and appearance of the product and the needle punching operation, and withstand the needle punching action.

The smaller the denier, the more preferable is the fiber as a material for constructing the base fabric 3. For example, extra-fine fibers of 1 d or less fineness or still extra-fine fibers of 0.1 d or less fineness are preferable. Such fibers can be easily produced by the removal of the matrix or the fibrilation of the composite fibers such as microconjugate fibers or fibrillose fibers. In the case of the microconjugate fibers, it is preferable that the matrix is polystylene and the core is polyester.

The preferable weight per unit area of the base fabric 3 is 50 to 250 g/m² in view of the flexibility, preference for lightweight furs, and hand. The strength of a base fabric of less than 50 g/m² is insufficient, while a base fabric of over 250 g/m² gives a hard hand.

Thus the artificial fur according to the present invention has characteristic properties, such as characteristic appearance and hand and an excellent varied surface, owing to the three-dimensional arrangement of the piles, which have not been realized in the conventional artificial furs, and gives a distinguished impression of a high-grade fur.

A method of manufacturing an artificial fur according to the present invention will be described hereinafter.

In manufacturing the artificial fur according to the present invention, the use of a nonwoven fabric as the base fabric 3 brings about satisfactory results. The artificial fur described hereunder employs a nonwoven fabric as the base fabric 3.

The nonwoven fabric is manufactured through a well-known process, such as the spun-bond process, the needle punching process, or the water punching process. The fibers to be used, the weight per unit area, and other conditions are determined by taking into consideration the above-mentioned conditions for the base fabric.

The film 4 of a suitable elastomer is formed over the surface of the base fabric 3, namely, the nonwoven fabric manufactured through the above mentioned process. The direct coating process, the transfer process, the elastomer film laminating process, or the impregnation process is applicable to forming the film 4.

Generally, the application of a solution of the elastomer in the solvent to the surface of the base fabric 3 is the simplest method of forming the film 4 and preferable in view of improved effect of adhesion of the film 4 to the base fabric 3 owing to the permeation of the elastomer solution into the base fabric 3. When a polyurethane resin is used, for instance, a polyurethane solution of 10 to 30% by weight polyurethane concentration prepared by mixing polyurethane and a solvent, such as dimethyl formaldehyde/methyl ethyl ketone (mixed solvent) is used. The preferable viscosity of the solution, in view of film formability is 5,000 to 15,000 cp. In the case of the impregnation process, it is necessary to cause polyurethane to migrate to the surface of the base fabric 3 so that polyurethane is distributed partially over the surface. Usually, drying the impregnated base fabric after impregnation causes polyurethane to migrate to the surface of the base fabric and increase in density over the surface. The higher the temperature, the more active the migration, therefore, the partial distribution of polyurethane over the surface is easily achieved by this method.

This process is new and has never been applied to the artificial fur manufacturing process.

The film 4 may be formed over one side or over both sides of the base fabric 3.

Then, piles 1 are implanted on the base fabric 3.

The piles are implanted through the needle punching process, in which the piles 1 to be implanted are spread over the base fabric 3 and needled with needles 6 for implanting the piles 1. Thus a single rising hair structure 8 or a plurality of rising hair structures 8 (desired number of rising hair structures) are formed over the base fabric 3 depending on the type of a needle board 5 employed in the needle punching process. For example, a needle board shown in FIG. 9 forms a single rising hair structure 8, while a needle board shown in FIG. 10 forms rising hair structures 8 of a number corresponding to the number of groups of needles. In either case, the piles 1 piled in areas corresponding to areas on the needle board 5 vacant of needles are not implanted and are removed completely in the following process. The length of the implanted pile 1 is dependent on the height of the needle 6 of the needle board, while the pile density is dependent on the density of the needles 6. The pile density can be also adjusted by regulating the amount of piles 1 spread over the base fabric 3. Usually, the pile density is adjusted by the latter from the viewpoint of the properties of the base fabric. For example, when the pile density in the central section of the band needs to be increased, the amount of piles in the central section is increased accordingly. When the length of piles implanted in the central section in the widthwise direction X needs to be greater than that of piles implanted in the peripheral sections, the length of needles disposed in the corresponding section of the needle board 5 is reduced as compared with needles in the side sections as illustrated in FIG. 11. Such specific requirements can be met also by changing the disposition of the base fabric 3. For example, when the base fabric 3 is fixed on a concave and curviform bed, not shown, and subjected to needle punching using a needle board 5 having needles 6 of the same lengths, the same effects result as mentioned above.

Thus, according to the present invention, in producing an artificial fur consisting of a plurality of bands 8, boundary sections 8 between the adjacent bands 8 of an optional design, such as having no pile 1 or as having a few piles, can be easily formed by properly adjusting the length of the needles corresponding to the boundary sections 8. In such a case, the selective decision of the type and the regulation of the amount of the pile 1 to be implanted in the boundary sections 9 is effective depending on the design. Accordingly, a wide artificial fur having a plurality of bands 8 of piles 1 disposed over the base fabric 3 so as to form interference fringes and having short under fur fibers implanted in a high pile density in the boundary sections can be easily produced by adjusting the width of the boundary sections 9 and the length of the piles 1 forming the bands 8.

The needle punching process may, if necessary, comprise a plurality of stages. For instance, in processing an artificial fur having a plurality of bands 8, a needle board 5 having areas vacant of needles 6 corresponding to the boundary sections 9 is used in the primary needle punching stage, and then a needle board 5 having needles 6 over the entire area thereof is used in the secondary needle punching stage, which improves the efficiency of the needle punching process.

Ordinary needles 6 are applicable to the needle punching process. Different needles 6 distinguished by the gauge and the morphology of the barb 7 represented by the height of the kick-up 7a, the angle 7b, and the length 7c and the depth 7 d of the throat as illustrated in FIG. 12 are arranged selectively in the central area in the widthwise direction X of the rising hair structure and in the peripheral areas of the needle board 5 to implant more guard hair fibers 1a than under fur fibers 1b in the central section of the band 8. For example, if needles 6 having short kick-ups with a small throat depth 7d are arranged in the peripheral areas of the needle board 5, more under fur fibers 1b than guard hair fibers 1a are implanted in the central section of the band 8, because such needles 6 have a tendency to implant finer fibers selectively.

FIGS. 12A, 12B and 12C shows exemplary kick-up type barbs 7. A barb 7 having a deep cut and a point protruding from the side of the needle stem has a tendency to implant piles 1 of large denier, while a barb 7 having a shallow cut and a point lying flush with the side of the needle stem has a tendency to implant piles 1 of small denier. Such tendencies are enhanced by the gauge accordingly.

A rising hair structure thus produced is, if necessary, sized with an aqueous paste such as polyvinyl alcohol for temporary fixation. However, this fixation is not essential to the present invention and advantageously may be omitted.

The rising hair structure is then subjected to shearing to remove the part of the implanted piles projecting from the back 3a of the base fabric 3. After shearing, if necessary, an elastomer solution is applied to the back 3a for the enhanced fixation of the implanted piles. Then, the rising hair structure is subjected to the raising process to raise up the piles 1.

When the base fabric 3 is formed of the microconjugate fibers or the fibrillose fibers, the rising hair structure is subjected to the softening process after shearing to soften the base fabric 3. In the softening process, the thickness of the component fibers of the bass fabric 3 is reduced by matrix removal or by fibrilation so that the base fabric 3 is softened. When the base fabric 3 is formed of composite fibers using polystylene as the matrix and polyester as the core, for example, a hydrocarbon halide, such as ordinary trichloroethylene, is used for the removal of the matrix.

Then, the rising hair structure is passed together with a liquid through a restricted space formed in an apparatus as shown in FIG. 8 to the characteristic lie of the hair, which is one of the objects of the present invention. This process also is a new process never before applied to the conventional artificial fur manufacturing process. In this process, a long textile product, such as a fabric, is subjected to physical actions as it is conveyed in a liquid together with the same. As the rising hair structure is conveyed in one direction, the piles 1 are restrained by the physical actions due to the movement of the rising hair structure, so that the desirable lie of hair is formed. These physical actions work more effectively on an objective article of a narrow width than on an objective article of a greater width. In this process, the objective article undergoes not only the restraining action, but also simultaneous flexing action and relaxing action. Accordingly, the objective article is softened through this process.

Those physical actions work on the rising hair structure in a restricted space. The restricted space is provided with a slit-form or a nozzle-form mechanism 14 as shown in FIG. 8B. The objective article passes the slit-like or the nozzle-like means 14 in a sheet-form or in a rope-form respectively.

With either means 14, the cross-sectional area in the widthwise direction X of the rising hair structure, i.e., the objective article, including the piles (as measured by applying a pressure of 1 g/cm² to the pile surface) is 5 to 60% of the cross-sectional area of the means 14 (area of the space of nozzles or slits). Naturally, it is possible to adjust the means 14 so that the dimensional relationship between the means 14 and the rising hair structure is established. If the above-mentioned dimensional relationship is satisfied, the movement of the base fabric 3 through the means 14 is impeded or the desirable lie of the hair cannot be formed satisfactorily.

Thus the objective article passes together with the liquid through the restricted space under a fixed restraint. The intensive restraint that works on the rising hair structure as the same passes through the restricted space exhibits a dexterous action to lay down the piles 1 in the central section of the rising hair structure in one direction and, simultaneously, to lay down the piles 1 in the rest of the sections diagonally outward with respect to the central section.

Ordinarily, the liquid is an aqueous solution, however, an organic solvent can be used if solvent treatment is required. In this process, it is also possible to carry out simultaneous conditioning of the lie of the hair and the dyeing or resin-finish treatment. A dye solution or a resin solution is used for the simultaneous dyeing or for the simultaneous resin-finish treatment as the processing liquid of the process.

The use of a high-velocity liquid enhances the above-mentioned actions and effects of the process, which is desirable to the present invention. A desirable high-velocity liquid is a liquid jet flow of 50 to 300 m/sec velocity.

A liquid-flow-processing machine is applicable as the processing apparatus 10. More concretely, examples of commercial liquid-flow-dyeing machines applicable to the process are the "Jet Dyeing Machine" (Gaston), "Circular" (Hisaka Seisakusho), "Dashline" (Oshima Kikai), and "Massflow" (Masuda Seisakusho).

In processing the objective article on the apparatus 10, the objective articles is looped along the processing passage of the apparatus 10 and the opposite ends of the objective article need to be joined together to place the objective article in the processing passage in an endless loop. The endless loop of the objective article is pulled successively into the processing passage by the liquid jet flow and is subjected to repeated restraint processing.

The manner of operation of the liquid-flow-dyeing machine will be described hereinafter with reference to FIG. 8A.

FIG. 8A is a general side elevation of the liquid-flow-dyeing machine. A pump 11 supplies the processing liquid heated at a heat exchanger 12 through a nozzle valve 13 to a nozzle 14. The liquid is injected through the nozzle 14. The dynamic pressure of the injected liquid causes the endless loop of the rising hair structure 15 to move through a lower tube 16 in a counterclockwise direction into a stagnation section 17. Thus the rising hair structure 15 is treated as the same circulates along the passage. A driving reel 18 to disposed above the nozzle 14 to enable the smooth circulation of the rising hair structure. Also shown in FIG. 8A are a reserve tank 19 for supplying the dye solution and chemicals, an opening 20 for putting the rising hair structure into or taking out the same from the apparatus, a pneumatic valve 21, and an inspection window covered with a pressure-resistant glass plate. FIG. 8B is an enlarged sectional view of the nozzle 14 of FIG. 8A. After passing the nozzle valve 13, the liquid is injected into the nozzle case 23 through a gap formed between a nozzle boss 24 and a nozzle pipe 25 so that the rising hair structure is moved vertically together with the liquid. A conical pipe 26 is provided to guide the rising hair structure for smooth movement. The liquid enters the conical pipe together with the rising hair structure from above the same.

The processing condition of the process is decided selectively considering the properties of the component fibers of the rising hair structure and the elastomer. In some cases, the liquid of a high temperature may be used, however, ordinarily the desirable temperature of the liquid is, in view of obviating the setting of the piles 1, in the range 30° C. to 135° C., preferably, 70° C. to 130° C. The duration of the treatment may be as long as necessary for achieving the objects of the invention. Ordinarily, the duration is 10 to 120 min, preferably, 30 to 60 min. Excessive duration of treatment can cause setting of the piles 1. When fiber-dyed piles 1 are used, in particular, the temperature of the liquid is, for example, as low as 70° C. to 80° C. in view of the coming-off of the dye.

The artificial fur thus manufactured according to the present invention has excellent characteristics, such as the excellent lie of the hair and recovery from rubbing against the lie of the hair, which have never been possible in the conventional artificial furs and are not at all inferior to genuine furs. The present invention also provides a method of stably and easily manufacturing such an excellent artificial fur through mass production.

The constitution and the method of the present invention has been described concretely hereinbefore. Now the embodiments of the present invention will be described hereinafter. However, it is to be understood that the embodiments discribed hereinafter are not restrictive, but rather are suggestive of the further development of the present invention, and the present invention is not limited thereto.

EMBODIMENT 1

A bundle of 3.5 cm diameter of polybutylene terephthalate fibers each of flat X-shaped cross section, 2.5:1 ratio of major axis to minor axis and 30 d filament fineness was wrapped in a sheet of paper and cut in a length of 35 mm. Then, the bundle of fibers was dipped in an aqueous caustic soda solution of 40% concentration and 105° C. temperature for 70 min to prepare double tapered guard hair fibers 1a 30 mm in length.

A bundle 3.5 cm in diameter of polyester fibers of 3 d filament fineness and circular cross section (number of crimps: 6 crimps/25 mm, percentage crimp: 5%) was cut into a 25 mm length. Then, the bundle was treated through the above-mentioned process to prepare double tapered under fur fibers 1b 17 mm in length.

The guard hair fibers 1a and the under fur fibers 1b were dyed black and dark brown respectively. After oiling and drying the fibers, the guard hair fibers 1a and the under fur fibers 1b were well mixed pneumatically at a mixing ratio of 50 to 50.

A needle punched felt of 150 g/m² weight per unit area was produced from microconjugate fibers each consisting of a polyester core component of 0.1 d fineness and polystylene matrix component (matrix-to-core ratio: 50 to 50). Then, the surface of the felt was coated with a film of 50μ thickness of a mixture of 20% polyurethane and 80% dimethyl formaldehyde at a wet condition, and the felt was then dried at 80° C. for 15 min.

Then, the other side, i.e., the surface not yet coated, was coated with a film of polyurethane in the same manner to finish with a nonwoven base fabric 3 coated with films on both sides.

Webs of the mixture of the guard hair fibers 1a and the under fur fibers 1b were spread in a uniform layer of 1500 g/m² over the base fabric 3.

Needles 6 were set up on a needle board 5 along the direction of advancement of the base fabric 3 in a width of 7 cm. Needles 6 of 36 G (FPD-1, 15×18×36×3.5, Organ Needle) were set up in the central section of 3 cm width with respect to the width of the needle board 5 and needles 6 of 40 G (FPD-1, 15×18×40×3.5, Organ Needle) were set up in the opposite side sections each of 2 cm width to form needle groups.

The 36 G needle has a needle length of 88.9 mm, 9 barbs, a 100μ throat depth, and a 50μ pickup height.

The 40 G needle has a needle length of 88.9 mm, 9 barbs, a 100μ throat depth, and a 50μ pickup height.

The layer of the guard hair fibers 1a and the under fur fibers 1b was needle-punched with the needle board 5 to a needle depth of 11 mm and needle-punching density of 400 needles/cm² to implant the guard hair fibers 1a and the under fur fibers 1b.

Then, the ends of piles 1 projecting from the back of the base fabric 3 were sheared with a hair clipper, and a two-component adhesive solution containing 20% polyurethane, 40% methyl ethyl ketone, and 40% toluene was applied to the back of the base fabric 3 and dried. After drying the base fabric, the piles 1 were raised to remove excessive guard hair fibers 1a and under fur fibers 1b. Then, the rising hair structure was subjected to aging at 60° C. for 24 hrs for the bridge formation of the two-component type polyurethane.

A solution containing 20% polyurethane and 80% dimethyl formaldehyde was applied to the back of the base fabric 3 1500μ in thickness by a reverse coater and the coating was subjected to wet coagulation. Then, after buffing the wet type urethane, the polystylene matrix of the base fabric 3 was removed with trichloroethylene.

The sectional area of the rising hair structure including the piles 1 along the widthwise direction X as measured by applying a pressure of 1 g/cm² to the pile surface was 29 cm².

Then, the rising hair structure was subjected to reduction rinsing and liquid-flow treatment on a "Circular" dyeing machine (Hisaka Seisakusho) equipped with a nozzle having a sectional area of 64 cm² in the nozzle space, at 80° C. for 30 minutes by using a liquid containing 1 g/l caustic soda, 1 g/l hydrosulfide, and 1 g/l surfactant. Then, after rinsing in hot water, the rising hair structure was dipped in a liquid containing a silicon softening agent for softening treatment. After brushing the pile surface, the rising hair structure was dried. Thus a unit artificial fur having a fur width of 7 cm and a dark mink tone was produced.

The piles 1 of the unit artificial fur were inclined along the longitudinal direction Y, the piles 1 in the outermost side sections of the fur were extending laterally at an angle of 60 degrees with respect to the longitudinal direction Y, and the piles 1 were inclined generally in a three-dimensional state.

The exposed base fabrics of ten pieces of the unit artificial furs were cut to form margins for seaming of 5 mm width on both sides of the fur section of each unit artificial fur, and then the unit artificial furs were sewn together with the lie of hair matched to form a wide artificial fur. The artificial fur had linear interference fringes along the seam line and a highly aesthetic appearance which cannot be found in the genuine fur.

EMBODIMENT 2

A bundle 3.5 cm in diameter of polybutylene terephthalate fibers each of flat X-shaped cross section, 2.5:1 ratio of major axis to minor axis and 40 d filament fineness was wrapped in a sheet of paper and cut to a length of 35 mm. Then, the bundle of fibers was dipped in an aqueous caustic soda solution of 40% concentration and 105° C. temperature for 90 minutes to prepare double tapered guard hair fibers 1a 28 mm in length.

A bundle 3.5 cm in diameter of mixed polybutylene terephthalate fibers of 5 d and 7 d filament fineness having round cross sections mixed in a mixing ratio of 50:50 was wrapped in a sheet of paper and cut to a length of 25 mm. Then the bundle was treated through the above mentioned process to prepare double tapered under fur fibers 1b 17 mm in length. The under fur fibers 1b were finished by oiling.

The guard hair fibers 1a and the under fur fibers 1b were opened and mixed pneumatically in a weight ratio of 40:60.

A needle-punched felt having a 100 g/m² weight per unit area was produced from microconjugate fibers (matrix to core ratio: 30:70) each consisting of a core component of 0.25 d polyester filament and a matrix component of polystylene. After coating the felt with a polyurethane film of 50μ thickness at a wet condition, the felt was dried at 80° C. for 20 minutes.

Webs of the mixed guard hair fibers 1a and under fur fibers 1b were spread in a uniform layer of 1800 g/m² weight per unit area over the coated surface of the base fabric 3.

A needle board 5 was divided widthwise into sections each including subsections of 2, 3, and 2 cm width, arranged in this order. Needles 6 of 36 G (needle length: 82.9 mm, number of barbs: 9, throat depth: 100μ , pickup height: 50μ) were set up in the subsections 3 cm in width.

Needles 6 of 38 G (needle length: 88.9 mm, number of barbs: 9, throat depth: 70μ , pickup height: 0) were set up in the subsections 2 cm in width.

The needle depth for subsections 3 cm in width was 11 mm and the needle depth for subsections 2 cm in width was 17 mm.

The layer of the guard hair fibers 1a and the under fur fibers 1b was needle-punched with the needle board 5 at a needle-punching density of 420 needles/cm² to implant the fibers 1a and 1b.

After shearing the ends of piles 1 projecting from the back of the base fabric 3 with a hair clipper, an adhesive solution containing 20% polyurethane, 40% methyl ethyl ketone, and 40% toluene was applied to the back of the base fabric 3 and dried. Then, the piles 1 were raised and excessive guard hair fibers 1a and under fur fibers 1b were removed. Then, the rising hair structure was subjected to aging at 60° C. for 24 hours for the bridge formation of the two-component type polyurethane.

Then, a solution containing 20% polyurethane, and 80% dimethyl formaldehyde was applied to the back of the base fabric in a thickness of 1500μ by a reverse coater and the coating was subjected to wet coagulation. Then, after buffing the wet type urethane, the polystylene matrix of the base fabric 3 was removed with trichloroethylene.

The sectional area of the rising hair structure including the piles 1 along the widthwise direction X, as measured by applying a pressure of 1 g/cm² to the pile surface, was 800 cm².

Then, the rising hair structure was dyed on "Circular" dyeing machine (Hisaka Seisakusho) equipped with a nozzle 14 having a sectional area of the nozzle space of 1963 cm², at 110° C. for 60 minutes by using a dye solution containing 15% by weight of Kayalon Polyester Black T (disperse dye, Nippon Kayaku). After dyeing, the rising hair structure was subjected to reduction rinsing at 70° C. for 30 minutes using a liquid containing 1 g/l caustic soda, 1 g/l hydrosulfide, and 1 g/l surfactant, and rinsed in hot water. Then, the rising hair structure was dipped in a liquid containing a silicon softener for softening treatment. Then, after brushing the pile surface, the rising hair structure was dried.

Thus, an artificial fur having a black mink tone with alternate arrangement of high sections of approximately 3 cm width and low sections of 2 cm width was produced.

The piles 1 of the artificial fur were inclined generally in the longitudinal direction Y. The lie of the hair of the high sections, as viewed from above the surface, expanded from the central section toward the opposite sides thereof, namely toward the adjacent low sections with the piles in the outer sections thereof inclining in greater inclinations with respect to the longitudinal direction Y, and the piles 1 in the outermost sections of the high sections on the opposite sides of the low section extended approximately at an angle of 30 degrees and overlapped each other in the central area of the low section lying between the high sections and formed a linear interference fringe.

CAPABILITY OF EXPLOITATION IN INDUSTRY

The artificial furs of the present invention are useful as clothing materials, such as for coats and shawls, decorative materials, and architectural decorative materials, such as for sofas, car seats, rugs, and tapestries. 

We claim:
 1. An artificial fur of a rising hair structure formed by implanting pile fibers through a base fabric, characterized in that the pile fibers are inclined generally longitudinally, as viewed from above the surface, the pile fibers in the widthwise central section of the rising hair structure extend in parallel to the longitudinal direction, the pile fibers in the opposite peripheral sections extend diagonally widthwise with respect to the longitudinal direction and the pile fibers in the outermost sections of the rising hair structure extend diagonally at angles of 10 to 80 degrees with respect to the longitudinal direction of the rising hair structure.
 2. An artificial fur according to claim 1, wherein the pile density of the piles in the central section of said rising hair structure is greater than that in the peripheral sections.
 3. An artificial fur according to claim 1, wherein the length of the piles in the central section of the rising hair structure is greater than that of the piles in the peripheral sections.
 4. An artificial fur according to claim 1, wherein a plurality of said rising hairs structures are joined widthwise in a plurality of units.
 5. An artificial fur according to claim 4, wherein no pile is provided in the boundaries between the adjacent unit rising hair structures connected widthwise.
 6. An artificial fur according to claim 1 wherein the pile consists of guard hair fibers and under fur fibers.
 7. An artificial fur according to claim 1 wherein at least the guard hair fibers among the pile fibers are the fibers having at least a tapered end.
 8. An artificial fur according to claim 1, wherein the width of the unit rising hair structure is 20 cm or less.
 9. An artificial fur according to claim 1, wherein at least one side of the base fabric is coated with a polymeric elastomer.
 10. An artificial fur according to claim 1, wherein fibers constituting the base fabric are extra-fine fibers of 1 denier or less fineness.
 11. A method of manufacturing an artificial fur, comprising steps of forming a rising hair structure by implanting pile fibers in a base fabric through a needle-punching process and passing the rising hair structure together with a liquid through a restricted space.
 12. A method of manufacturing an artificial fur according to claim 11, wherein said restricted space is a slit-like or a nozzle-like means.
 13. A method of manufacturing an artificial fur according to claim 11, wherein a step of passing a rising hair structure together with a liquid through said restricted space is a liquid flow treatment apparatus with a high-velocity.
 14. A method of manufacturing an artificial fur according to claim 11, wherein a needle board having a plural kinds of needles differing from each other in at least the number of the barbs or the shape of the barbs in individual needle is employed in the needle punching process.
 15. A method of manufacturing an artificial fur according to claim 11, wherein a needle board having needles the needle depth of which are different from each other in a central section and in a side sections of the board is employed in the needle punching process.
 16. A method of manufacturing an artificial fur according to claim 11, wherein a needle board having areas without needles are provided intermittently in widthwise direction is employed in the needle-punching process.
 17. A method of manufacturing an artificial fur according to claim 11, wherein a film of an elastomer is formed on at least one surface of the base fabric prior to implanting piles through the needle punching process.
 18. A method of manufacturing an artificial fur according to claim 11, wherein a needle board having such a needle arrangement that a needle depth is varied intermittently in widthwise direction and linear like grooves created by difference in said needle depth are provided in the longitudinal direction is employed in the needle punching process. 